DE2105291B2 - Mobile subscriber set for a radiotelephone system - Google Patents

Description

The invention relates to a mobile subscriber set according to the preamble of claim 1.
In a radio telephone system which works together with the public telephone network, various problems arise at the beginning of the call on the part of a mobile subscriber or a stationary subscriber, ie a subscriber connected to the public telephone network. A first problem is the automatic search of the mobile subscriber set for one of the voice radio channels over which the calls are transmitted from the mobile subscriber to the stationary subscriber, from the stationary subscriber to the mobile subscriber and from the mobile subscriber to a mobile subscriber. After a free radio channel has been found, the problem arises of the consistent transmission of the digits forming the identification number of the mobile subscriber and, if the call originates from the mobile subscriber, the digits forming the number of the called subscriber. The digits must be transmitted one after the other without errors, as a transmission error would result in an interruption in the connection and inconvenience for the participants. When the mobile subscriber lifts the handset (if the subscriber calls) or when the call sign is received in the mobile set (if the subscriber is called), there is also the problem of powering the circuits in the mobile subscriber's device, which must be able to be switched on and off automatically , since manual actuation, especially in a motor vehicle, would endanger the driver and others.

In the Italian RTMI system (Radio Telefonico Mobile Integrato) are a specific fixed one-way radio channel for those from the fixed control center to the mobile subscribers ongoing calls and a different number of two-way radio channels for Intercom provided. As a result, all mobile subscriber sets remain on the same channel tuned to receive callsigns and occupy one of the intercom or talk radio channels for the connection or for the start of the call.

From DE-OS 15 12 871 an automatic radio telephone system is known in which the connection between the mobile participants among themselves or with a stationary participant essentially is controlled by a special circuit arrangement in the fixed exchange. There are for this purpose a connector with a multiple switch that controls the system's group selector can connect directly to the circuits of the radio channels, and a marker assigned to the radio channels and appropriate registers are provided. Such changes to the public switching system are often undesirable. In addition, in the known system, the vehicles have to be relatively smaller in one area Remain away from the associated switching system.

Based on this prior art, the invention is based on the object of a subscriber set indicate that is in a relatively large area without significant changes to the switching equipment of the public telephone network can automatically search for a free radio channel and then not longer than necessary

This object is achieved by the subscriber set characterized in claim 1

The invention is particularly suitable for the Italian RTMI system and will be used in context

described with this system. The automatic search for a voice radio channel on which the conversation can be conducted or a call can be started by the mobile subscriber takes place in the present invention in that the distribution of the mobile subscribers to the radio channels happens at random, ie by determining the channel selector of the mobile Subscriber to the position which corresponds to the channel last occupied by the mobile subscriber in a previous conversation. This reduces the probability that several participants will want to occupy the same channel at the same time and thus make the conversation impossible, and the times for the occupancy of the individual channels are limited. As soon as a free channel is found, the transmission of the digits of the identification number of the subscriber who may be called is controlled according to an embodiment of the invention so that the sequential transmission of the digits is adapted to the code type (after frequency separation) of the specially used RTM! System will. The automatic switching on of the devices of the mobile subscriber is, if the mobile subscriber calls, controlled by the hybrid circuit of the handset by means of a signal that detects their position (ie lifted or hung up). If the mobile subscriber is called, the automatic switch-on is effected by the call sign. The circuitry of the mobile subscriber is triggered automatically at the end of the call or when it is not possible to establish the connection. The advantages of the invention are listed below:
a) It is possible to noticeably reduce the time required for the broadcast of the choice and to make it independent of the user. According to the current state of the art, the user must dial the number of the subscriber he wishes to call by means of a rotary dial or a keyboard, the time span necessary for sending the choice being in the order of magnitude of a few tens of seconds. You; Invention makes it possible to shorten this period of time to about one second. A user-independent duration of the broadcast of the choice is obtained by dialing the choice number and automatically transmitting it. This preselection is carried out by the user (using a single rotary selector in the manner of a »thumb wheel«) on a dial preparer on which the dialing number remains until the user selects another number. This enables the preselection to any one Time and sending of the same by means of a dial send button. The automatic transmission is carried out by means of an electronic digger and a repetition converter, which have the task of transmitting all digits in a consistent manner and, if several identical consecutive digits occur, to send a repetition character instead of the second (fourth, sixth, etc.) digit. This avoids any possible mistakes made by the user. The special signal code type (after frequency separation) in the Italian RTMI system does not allow the transmission of the same code combinations in succession, as they cannot be recognized as different by the fixed control center,
b) The likelihood that several mobile subscribers will occupy the same call channel at the same time, and consequently the impossibility of establishing the connection, can be reduced by allocating the mobile subscribers to the radio communication channels by setting the channel selector in

at rest on the last of the moveable Participants for a conversation occupied channel is made dependent on chance, with which the Occupation times of the individual channels can be limited.

c) It becomes possible to use only two signal generators instead of six for the transmission of necessary generators encrypted in a 2-out-of-6 code.

2 (i An embodiment of the invention is based on described in the drawing. It shows

F i g. 1 the block diagram of the device of the mobile participant,

F i g. 2 the circuits of the control unit for the signal generators,

Fig.3 the circuits of the identification and Election mailing list,

F i g. 4 the circuits of the program control unit and

F i g. 5 the signal curves for the operation of the repeater converter.

In the block diagram of the movable device are shown in FIG. 1 following units available:

Unit PS

Control panel in which control, control and signaling devices and the handset are included are;

Unit R _x S

Receivers for the signals corresponding to the monitoring processes and for the reporting signals;

Unit G _t

Signal generator;

Unit G ₂

Signal generator;

Unit R _x T _x

consists of a transceiver that both sends and receives _{signals TO and calls;}

Unit DL

logical selection and conversion device with circuits for controlling selection and conversion, which are put together in the following units:

The unit D / 5 is an identification and selection distributor which is able to deliver the control signals to the generator control unit CG in a chronological order;

fao The unit CG is the control unit of the signal generators G \ and Ch and supplies them in chronological order with the commands for the transmission of the tone combinations corresponding to the code used according to frequency separation;

The Er unit is a program control unit for controlling and generating the monitoring signals. This unit It provides the control signals for the entire mobile device.

The flow of signals between the various blocks is based on the description of the figures below emerged.

The signals labeled A in FIG. 2 reflect the identification or dialing digits; these digits are encoded in a weighted and balanced 2-out-of-6 code, the values of which are R, 7,4,2,1,0.

Code table X X X X X X X movable to X X stationary X Attendees Digit 0 Signals from / = 3 (2) F ₄ (4) X X F ₅ (7) F ₆ X (R) Section 1 F ₁ (O) F ₂ (I) X X X X Section 2 Clause 3 χ χ X Clause 4 X X Clause 5 Clause 6 Clause 7 Clause 8 X Clause 9 X X Digit R X begin the news 0) end of news (F)

The code table shows the special 2-out-of-6 code used in the RTMI system. For each code combination to be transmitted, only two of the 6 A inputs are active; the signals A are digital signals and come from the identification and selection distributor DIS (FIG. 3). The output signals Sund Cs are digital signals which operate the signal generators 1 and 2 and which control the transmission of the code combinations (according to the tone combination) which correspond to the signals to be transmitted. The generator control unit contains two circuits, each of which controls a generator. They are characterized by the fact that one gives priority to the higher values and the other to the lower ones. This means that the higher values, if one understands the higher values in a sequence decreasing from R to 0, have priority when accessing generator 2, while the lower values in the sequence 0, 1, 2, 4, 7, R have priority when accessing the Have generator 1. Let us assume that the digit 6 is to be transmitted: The signals A corresponding to the values 4 and 2 change their original logic value 0 to the logic value 1 for a period of time corresponding to the transmission time of the digit itself. The signal corresponding to the value 4 could activate the NAND circuits 5 and 8, while the signal corresponding to the value 2 could activate the NAND circuit 7 and the NAND circuit 6. The term "NAND circuit" is used here and in the following to denote a logical combination circuit that performs an inverted AND function, that is, the output of which has a logical 0 if and only if all inputs have a logical 1. In reality, however, only the NAND circuit 5 and the NAND circuit 6 remain active because the output of the NAND circuit 5, which has changed from I to 0, blocks the NAND circuits on which the signals with a lower value arrive and thus also the NAND circuit 7. Therefore, the signal which corresponds to the value present at the input of the NAND circuit 7 does not switch the output of the NAND circuit 7 itself from 1 to 0 and only the signal F4.2, which corresponds to the send command for the frequency F4, it is passed to the generator 2. On the other hand, as far as the control of the generator 1 is concerned, only the output of the NAND circuit 6 is active. Also, when the NAND circuit 6 changes from 1 to 0, the inputs of the NAN D circuits 8 and 10 are blocked and therefore only the command corresponding to the transmission of the frequency F3 reaches the generator 1 (signal F _3. ,).

ι · -. In the rest position, all entrances, as shown in FIG. 2 is reproduced, the logical value 0, and accordingly all outputs have the logical value 1; under these conditions the generators 1 and 2 do not transmit a single frequency. The essential blocks of the in FIG. 3 are the following:

an electronic selector SE, consisting of a counter Q and a decoding matrix Mr, an identification coder CI, consisting of the N AN D circuits 81,82,83,84,85,86,87,94,95,96 , 97, 98, 99, 100, 101, 102, 103, 104, 105 and from a matrix Mr,

a choice coder CS, consisting of the NAND circuits 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65 and jo from the matrix Mr,

a repetitive converter CR, consisting of the NAND circuits 22, 23, 24 , 25, 26, 27, 28, 29, 30, 31, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, a comparison circuit CCon made up of the j3 NAND circuits 51 and 52 and a special flip-flop circuit Fi, the mode of operation of which is evident from the description below (circuit type “set-reset master and slave clockato «); the NAND circuits 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, the outputs of which form the inputs of the comparison circuit CCon of the repetitive converter CR ; the NAND circuits 53,54,67,68,69,70,71,72,73, 74, 75, 76, 77, 78, 79,80, 81,82,83,84,85,86,87, 88, 89, 90, 91, 92, 93, whose task is to code the monitoring signals and to control the dialing encoder;

the NAND circuit 72, the output of which has the purpose of setting the electronic selector SE to the idle state via the program control circuits fr at the end of the selection transmission;

an election preparer PrSe, which is contained in the control panel, but shown in FIG. 3 is included in order to better explain the operation of the repetitive converter CR;

«A commutator K for the transmission of the two signals P ₉ and Ρίο, depending on the occupied contacts; Said signals have the task of putting the electronic voter at rest at the end of the identification transmission via the program control unit Er. Depending on whether there are six or seven identification digits, the signal P ₉ or Pio is forwarded to the program control unit Ei.

The following is the mode of operation of the various Elements considered.

hi The activation of the electronic selector is controlled by switching on signals 5 and 5 °. These signals become effective in accordance with the activation of the signals Al and ΔΤ. In the

Activating the signals Sund S °, the counter begins counting by successively accepting the 16 individual possible states of the 16 possible combinations of the binary variables Qo, Qu Qz, Qi . The inputs of the decoding matrix M \ take the 16 possible states of the 16 possible combinations of the binary variables Ao in a corresponding manner,

These 16 possible states each correspond to the excitation of one of the 16 output lines of the decoding matrix M (ie there is an assignment of each of the 16 states of the 4 binary input variables mentioned to the excitation of one of the output signals labeled with the letters Po- - P15).

As shown in FIG. 3 is sufficient in the present case special case a voter with only 13 steps. Therefore the last three are labeled Pn, Pm, P15 Decoding matrix outputs not used.

In the idle state of the electronic selector SE , the counter reset signal S ^{0 has} the value 0 and the feed signal is blocked. As a result, the outputs of the counter Q assume the first of the 16 possible states to which the excitation of the first of the 16 output lines of the decoding matrix A ^ corresponds; ie in the idle state the output Po is activated with the logical value 0, while all other outputs have the logical value 1. Immediately after the feed signal S of the counter appears and after the zero ^{setting signal S 0 changes} from 0 to 1, the counter starts counting by, as already said, assuming all of its possible states and successively all outputs Pi, P2, P ^ .. . P15 of the decoding matrix M \ excited, ie to logic 0 brings

Let us now examine the operation of the identification coder, using the one to be transmitted as an example Identification message / 35579 ° is captured.

It should be noted that any number of identifications to be transmitted must be preceded by the representation / of the "start of the message" and that it must always be followed by the representation F of the "end of the message".

The two values 9, which are the sixth digit of the

Identification number are given, is the following noticed:

a) The presence of the value 0 of the sixth digit (ie / 355790 F) corresponds to the case that the mobile subscriber has been called;

b) The presence of the value 1 of the sixth digit (i.e. / 355791 ^ corresponds to the case that the mobile subscriber calls

The identification coder CI is controlled by the outputs P ₁ ... P _{9 of} the electronic selector SE and by the signal G *. which indicates the position of the hook switch of the handset, controlled The operation of the coder CI is possible by switching on the signal Δ I , which with its transition from 0 to 1 blocks the NAND circuits 100,101, 102,103,104,105 of the encoder output

With the first feed pulse S, the electronic selector SE changes from its idle state, which corresponds to a 0 at the output P ₀ , into the next of the 16 possible operating states, which corresponds to the transition of the output P \ from the logical value 1 to the logical value 0. Correspondingly, the rail of the decoding matrix M2 of the identification coder CI marked with the letter / becomes effective, and the combination /, "Beginning of the message" appears at the outputs A via the NAND circuits 97, 99, 103, 105 and 91, which is in the The code used is characterized by the effectiveness of the values 1 and R.

At the following feed impulse the effective signal goes from the output Pi to the output P>, i.e. the output Pi of the electronic selector SE returns to the logical value 1 and at the same time the output P2 of the electronic selector SE becomes effective by changing from the logical value 1 changes to the logical value 0 The rail 1 of the matrix M2 is now correspondingly effective.

In the example shown, the combination for the first digit (here: 3) is switched on

If the identification number to be sent contains two identical digits in a row, the second digit is not transmitted with the code combination that corresponds to the digit itself, but with the combination that corresponds to the repetition character that was created in the code used by activating the values R and 0 It should be noted that in the example given, a number consisting of six digits plus "beginning" and "end of message" was thought of. The in the F i g. 3 enables an identification number of up to six digits to be transmitted. The NAND circuits 81, 82, 83, 84, 85, 86, 87 have the task of determining, depending on the logical value of the signal C * , whether the last identification digit indicates the case of the calling or the case of the mobile subscriber called by they activate either the rail 6c (or 7c) or the rail 6r (or 7 «) of the matrix M2. The identification message is terminated by the transmission of the representation F for "end of message"

_ F is transmitted according to the effectiveness of the output P ₈ or P _{9 of} the selector SE , depending on whether the identification contains 6 or 7 digits. After the transmission of F , the output P ₉ or Pi ₀ becomes effective. This brings about the return of the zero signal S ° of the electronic selector to 0 by means of the program control unit Er (see FIG. 4), the blocking of the feed signal S of the selector, and the return of the operating signal Δ I for the operation of the identification encoder C / to 0.

The operation of the dialing coder CS is explained below. The dialing coder CS has the task of switching on a code combination corresponding to the effectiveness of each individual rail Vo .., V ₉ at the output of the dial preparer PrSe. The operation of the selector encoder CS is controlled by the operating signal Δ Τ . The activation of the signal Δ T, ie

its transition from logical 0 to logical 1 occurs simultaneously with the effect of the input signals S and S ° of the electronic selector SE, which by means of the repetition converter CR and the choice preparer PRSE the Wahlcodie-

M) rer CS controls

The activation of the signal Δ Γ switches on the operation of the electronic selector SE and on the other hand enables the transition of the output of the NAND circuit 66 from 1 to 0

h5 transmission of the code combinations present in the matrix M _{1 of the dialing coder.} The activation of the signal jd 7 "and the subsequent transition of the output Po of the electronic selector SE from 0

namely to 1 let the output of the NAND circuit 54 go from the logic value 0 to the logic value 1. Since the output of the NAND circuit 51, which is part of the repetition converter, is at 1, the output of the NAND circuit 66 goes from the r, logic value 1 to the logic value 0 and, as a result, the output of the NAND circuit 65 goes from logical value 0 to logical value 1. This opens the NAND circuits 60, 61, 62, 63, 64 and thus allows the code _{combinations present on the matrix Mj ια to} be passed over to the output A. In particular, switching the output Ψ \ (corresponds to the first step of the selector SE) from 1 to 0 via the NAND circuits 67, 68, 79, 76 and 73, 74 the effectiveness of the code combination for the signals 1, ^ and R , which corresponds to the character / for the beginning of the message. Moreover, the output goes Q of the flip-flop F 1 on because the 5am to the signal input Cp prevailing logic switching state at the inputs S 'Cwechselt (S'auf C'auf 1 and 0).

It should be noted that the choice preparer may transmit PRSE a dial number of a maximum of 10 digits, when taking advantage of it to the utmost capacity The electronic selector SE aktiviert_nach transmitting the 10 digit output Pn which ^r via the 2> NAND circuit 71 and the NAND circuit 72 makes the signal Z effective. In addition, the output of the NAND circuit 71 switches on the code combination F for "end of message" via the NAND circuit 69 and the NAND circuits 80, 77, 73, 74, which corresponds to the activation of signals 2 and Λ

If the pre-dialer PrSe is not used to its full capacity, but you want to transmit a dialing number with fewer than 10 digits (e.g. only 9 digits), you must add the number X to the number dialed on the dialer PrSe . As soon as the selection step setting the preparer PrSe to the digit X has taken place, the output Vx of the preparer and the NAND circuit 72 via the N AND circuit 71 and the NAND circuit 72 become effective. The code combination F for "Ejide of the message" is switched on via the NAND circuits 69, 80, 77, 73, 74. As soon as the signal Z returns to the logic value 1, the program control unit Er automatically blocks the advance of the v, selector and, by switching the signal S ³ to 0, returns it to the idle state.

The operation of the repetitive converter CR will now be considered. The comparison circuit CCon has the task of making the comparison between two consecutive digits of the dialing number. If the two compared digits turn out to be different from one another, the comparison circuit enables the second digit to be transmitted after the first digit has been transmitted. If, however, the two v, out compared digits as equal to each other, the comparison circuit enables transmission of the first digit after the transmission of the repeat character indicated by the effectiveness of the signals 0 and R in place of the second digit. mi

For the functional description of the comparison circuit CR it is assumed that a certain dial number is programmed in the dial preparer. The election information to be transmitted is z. E.g. the string / 02 7795558F. In this case, too, the _b · » message consists of the dialing number and the characters / for» start of message «and F for» end of message «. The dialing number consists of an area code 02 and a call number of the fixed subscriber, which consists of seven digits. So here we have the case of a nine-digit number.

It is assumed that the electronic voter SE at the level corresponding to the first digit, stands. The first digit is "0"; H. the rotary selector on the dialer that corresponds to the first digit on the "0" position. In this case, the logic value 0 present at the output of the NAND circuit 22 the logical value 1 at the output of the NAND circuit 32 result.

The other input of the NAND circuit 41, which is on The output of NAND 13 is located and has the logical value 0, generates the logical value 1 at the output of the NAND circuit 41.

The outputs of the NAND circuits 42, 43, 44, 45, 46, 47, 48 and 49 are all in a similar manner to the logical value 1 because at least one of the two inputs is set to 0 for all of the respective NAND circuits 14,15,16,17,18,19,20, 21 incoming inputs show the logical value 0. This has the consequence that the output of the NAND circuit 50, the inputs of which are all at the logical value 1, has the logical value 0. As a result, the output of the NAND circuit 51 is 1 and the selection encoder CS can Transmit code combination that corresponds to the first dialing digit. When the voter moves on to the next Step, which corresponds to the second digit, the logic state at the output of the changes NAND circuit 50 does not. None of the NAND circuits 41, 42, 43, 44, 45, 46, 47, 48, 49 dated logical value 1 to logical value 0. An analogous situation arises when the electronic Voter has switched to the step corresponding to the third digit.

When the voter starts scanning the fourth digit, which is equal to the preceding digit, then the comparison circuit applies the logic value 1 to the outputs of the NAND circuit 50. Namely, if the electronic selector is on the stage for the fourth digit, has the output of the NAND circuit 15 has the logic value 1. The output of the NAND circuit 25 has the logic value 0. Since this output with the output of the NAND circuit 24 in the dial preparer PrSe via the contact arm of the rotary selector for the fourth digit, the Rail Vj for the digit 7 and the contact arm of the rotary selector for the third digit is connected, the outputs of the NAND circuits 24 and 25 are short-circuited together. Therefore the logic value 0 present at the output of the NAND circuit 25 is also at the output of the NAND circuit 24. As a result, the output of the NAND circuit 34 has the logic value 1, so that the two inputs of the NAND circuit 43 are both at the logic value Worth 1 wins. Of the two inputs of the NAND circuit 43, one comes from the NAND circuit 34 and the other from the NAND circuit 15, of which it has already been said that they are at I. This has the consequence that the output of the NAND circuit 50, which has an input at 0, is at the logic value 1

The 1 present at the output of the NAN D circuit 50 causes, since the output Q of the flip-flop Ft is also at 1, the transition of the output of the NAND circuit 51 to 0 and via the NAN D circuits 66 and 65 Blocking of the outputs of the dialing encoder CS and

The transmission of the code combination for the repetition character via the NAND circuits 52, 70, 73, 74, 78, 75. At the same time, the inputs _{S 'and C "of the flip-flop F t change} their state (S' to 0 and C" to 1). The flip-flop Fi switches its output ζ) to logic 0 when the feed signal subsequently appears at input Cp, which prevents the transmission of two consecutive repeat characters.

The case is now dealt with in which the election preparer has at least three consecutive Digits are the same, which applies to the sixth, seventh and eighth digits in the example chosen, each with a 5 represent.

For the second digit with the value 5, the π yields Comparison circuit the result "equality", d. H. a 1 appears at the output of the NAND circuit 50, whereupon the code combination for the repeat character is transmitted.

During the following step (ie during the scanning of the third digit with the value 5) this causes the 0 at the output of the NAN D circuit 51 to be transferred to the flip-flop Fi and therefore the output Q of the flip-flop Fi to be skipped from 1 to 0. During the scanning of the third digit of the value 5, _>"> although the logic value 1 is at the output of the NAND 50, this logic value 1 is blocked by the fact that Q is at 0. Nevertheless, the output remains the NAND Circuit 51 and the operation of the dialing encoder, which transmits the combination corresponding to number 5 to outputs A , is not interrupted.

For a better overview of the operation of the repetitive converter, refer to the one shown in FIG. 5 referenced diagram, which reproduces the signal course over time for the example under consideration. According to FIG. 3 in the present example, the tenth digit is the character X, which corresponds to a position of the rotary selector for preparing the transmission of the code combination for "end of message".

As soon as the electronic selector scans the rotary selector in position X , the line Vx of the preparer output becomes effective, which via the NAND circuits 71, 69, 73, 74, 80, 77 the transmission of the code combination F for »end of 4> message «Controls

The program control unit Er shown in FIG. 4 consists of two parts: a continuously fed upper block BSup and a normally non-fed lower block BInf. > c

The upper block BSup contains: a memory (bistable flip-flop Bs), also called "switch-on memory", which has the task of controlling the feeding of the normally unpowered units of the mobile subscriber; two NAND circuits v. 110 and 111, which have the task of controlling the switch-on memory; a memory (bistable flip-flop Bi), which stores a logical signal of the content "on-hook handset"; a switch for the supply circuit //; a switch-on delay circuit CAR; a memory (bistable flip-flop circuit ßii), which by means of the NAND circuits 131 and 132 controls the tuning of the transceiver R _x T _x (by means of the signal L) to a special call channel (one-way radio channel from the stationary w to the mobile receiver); a ring counter CA and the NAND circuits 139, 140, 141, 142, 143, which use digital commands to control the tuning of the transmitter R _x T _x to the communication channels in a binary code.

The lower block β / n / contains: a supervisory signal decoder DSS; a timing pulse generator GT; a delay counter CR; eight memories (bistable multivibrators B ₂ , B ₃ , B ₄ , B ₆ , B ₁ , B », B ₉ , Bio); various NAND circuits 109, 115, 116, 117, 118, 119, 120, 121, 122, 123,124,114,139,112,113,130, 133, 125,126,129, 127, 128, 134,135.

In the following, the operation of the various assemblies will be considered.

The switch-on memory B ₅ is activated in the following cases:

- Receipt of a callsign which originates from a stationary or from another mobile subscriber and which corresponds to the activation of the signal Ma;

- Start of the call from the mobile subscriber (the mobile subscriber lifts the handset from and consequently the signal G becomes effective).

Let us first consider the case of receiving a callsign.

The signal Ma changes from the logic value 0 to the logic value 1, and when the handset is on-hook, ie at the logic value 1 of the signal G and the output of the NAND circuit 112, the bistable trigger _{circuit S 5 is} activated by means of the NAND circuit 110 Control command supplied, which closes the switch It for the supply of the normally unpowered units of the mobile participant. In addition, the output of the circuit CAR changes from the logic value 0 to the logic value 1 with a certain delay. The transition of the output of the circuit CAR from 0 to 1 continues with the help of the NAND circuits 131 and / 132 the command to tune the transceiver to the call channel (L changes from 0 to 1) and enables, by means of the NAND circuits 139, 140, 141, 142, 143 the expiry of the commands D for the tuning to the voice channels and allows the forwarding of the feed signal to the counter CA by means of the NAND circuits 125 and 126. In this way, the counter then tunes the transceiver R _x T _x to the call channels by starting from the channel that was occupied in the last call made by the mobile subscriber. If the mobile subscriber starts the call by picking up the handset, switching the signal G from 0 to 1 activates the switch-on memory.

When the handset is on-hook, the memory Si is in such a state that the corresponding input of the NAND circuit 111 jj the logic value 1 Jiat. At the same time, the signal has Ydev. logic value 1 (Y \ si a signal which allows the blocking of the calls originating from the mobile subscriber and initiated by the mobile subscriber), and the output of the NAND circuit 112 deceives, since the part BInf is not yet fed, at the input of the NAND Circuit 111 has the logic value 1 in front.

The output signal of the circuit CAR toggles all of the bistable flip-flops B ₂ , B ₃ , B ₄ , B ₆ , B ₇ , B ₈ , ßg, ßio existing memory from the zero position during the transition from 0 to 1. As soon as the said signal changes to 1, since the output of the flip-flop B ₂ connected to the NAND circuit 125 is correspondingly also at 1 and since the output of the memory Bu is also at 0, the output of the

Time pulse generator GT coming signal run through the NAN D circuits 125, 126 and control the advance of the counter CA.

There are two different cases ζ ν. In the first case, the ready signal can be present on one of the channels which the channel selector is scanning. The presence of this signal corresponds to the activation of output D of NAND circuit 107 via the decoder circuit of the monitoring signals. With the transition of the signal £> from the logic value 1 to the logic value 0, the memory consisting of the bistable multivibrator Jh is excited. This causes the blocking of the advance of the counter CA via the NAND circuit 125, whereby the transmitter-receiver will remain tuned to the currently reached channel addition, the same output excite the memory Bi the group consisting of the flip flop Bs memory which the Einschaltespeicher is the transmitter Namely As soon as the signal T exiting from the memory Bs changes from 0 to 1, the transmitter of the mobile subscriber is switched on. The signal D also excites the memory consisting of the bistable multivibrator Bt. This makes the signal .DELTA.I effective by means of the NAND circuit 134, which enables the operation of the identification encoder C / in the transition from 0 to 1 (FIG. 3). The same output of the bistable multivibrator B ₆ controls the switching of the signal 5 ° from 0 to 1 by means of the NAND circuit 127, whereby the operation of the counter of the electronic selector SE (FIG. 3) is allowed. The output of the NAND circuit 127 also allows the passage of the feed signal of the electronic selector SE (FIG. 3) during the transition from 0 to 1 via the NAND circuit 129. After transmission of the combination F for "end of message" of the identification, the signal Ρ9 // Ί0 is activated, which brings the bistable toggle switch B ₆ to rest when switching from 1 to 0. This causes the signal .DELTA.I to go back to 0 and the signal S ° also goes back to 0 via the NAND circuit 127, and the feed signal S of the electronic selector SE is blocked via the NAND circuit 129 (FIG. 3). As a result, the counter of the electronic selector SE ( FIG. 3) loses the feed signal 5 and at the same time receives the zero setting signal 5 ° at its input.

The second case is that the counter CA runs through a full round without finding a single radio channel ready. In this case, the delay counter CR via the NAND circuits 130 and 117 is set by UEN output of the on-delay circuit CAR in transition, and after he has the complete number of sampled voice channels reaches the appropriate step, it activates the output of the NAND circuit 124 from 1 to 0, whereby the bistable flip-flop BiI is switched over. The transition of the signal RO from 0 to 1 causes the output of the NAND circuit 112 to be switched immediately to 0 with m> subsequent switching off of the switch-on memory B ₅ and the return when the handset is on-hook (G to 0) via the NAND circuits 123 and 113 of the whole moving device to sleep.

If, however, the handset is lifted, the transition of the signal RO from 0 to 1 controls the switching on of a special lamp on the control panel PS, which indicates to the mobile subscriber that the call cannot be made because no channel is available In this case, as soon as the mobile subscriber hangs up the handset, the output of the NAND circuit 112 goes to 0, the switch-on memory Bs is switched off, and the device of the mobile subscriber returns to the idle state. It should be noted that each time the power is withdrawn, all circuits with the exception of the ring counter CA automatically return to the rest position. The ring counter remains blocked on the channel occupied by the mobile subscriber for the last transmission carried out

Let us now return to the case where a free channel was found. At the end of the transmission of the identification message and after the signal .DELTA.I has returned to 0, the logic signal ^ by transition is via the bistable multivibrator B 10 and via the NAND circuit 135 at the logic value 1 of the signal G '(hybrid circuit of the handset) effective from 1 to 0. The Signair ¹ allows the stationary control center to determine the position of the hybrid circuit of the mobile subscriber. In other words, the logic value 1 of the signal t = means that the mobile subscriber's handset has been lifted after the identification transmission. The logic value 0 of the signal P indicates that the mobile subscriber's handset has hung up after the identification transmission mobile subscriber depending on whether he called himself or whether he was called by another subscriber, either the signal from the control center (in the receiver of the handset) or the signal for the; acoustic alarms. This signal is marked with // and is made effective via the monitoring signal decoder DSS (more precisely via the NAND circuit LOS of the decoding itself) corresponds to a logic 1 of the signal G

Let us consider the case that the mobile subscriber is the caller. It was said that in this case if the identification is correctly transmitted and has been received by the fixed center, the mobile subscriber receives the signal from the center receives what confirms the connection with the control center and sends him the choice empowered

Sending the Wahl_geht means of a button in front of which from 1 switches the signal T ₅ to 0, and makes thus effectively If adjacent to the Nand circuit from the output of the 109 next input, all the other inputs of the NAND circuit 139 to 1 at the same time, the output of the NAND circuit 139 changes from 1 to 0 and activates the memory consisting of the bistable multivibrator B ₁ , the output of which passes through the NAND circuit 128 the operating signal for the selector encoder CS (see FIG. 3) Switching from 0 to 1 takes effect

The output of the bistable multivibrator B _{1 also} causes the electrical selector SE of the selection identification distributor DIS to be ready via the NAND circuit 127 under the same conditions as were already described above for the identification transmission. All inputs of the NAND circuit 139 are only at 1 and their output can therefore only change to C when the dial send button is pressed if the following conditions are met:

The identification must have been sent, dei

The transmitter must be switched on, the handset must be lifted and the signal for the acoustic Wake-up call must not have been received.

The end of the transmission of the election information is indicated by the activation of the Z signal. If j the signal 7 changes from 1 to 0, the bistable trigger circuit Βη is reset via the bistable trigger circuit Bi and the NAND circuit 114 to the rest position. As a result, the signal A Γ returns to 0 with the help of the NAND circuit 128 (idle state), in and by means of the NAND circuits 127 and 129 the electronic selector SE of the selection identification distributor DIS is given the zeroing signal and the feed signal is taken. If, after the identification transmission, the fixed center recognizes the call as originating from the fixed subscriber, the mobile subscriber receives the signal for the acoustic wake-up call, which corresponds to the activation of the signal H at the output of the NAND circuit 108 of the monitoring signal decoder. As already said before, the signal H can only be effective when the handset is on-hook. The activation of the signal Π corresponds to the activation of the bell in the mobile device. The mobile subscriber, if present, lifts the handset, which causes the transition of the signal r from 0 to 1, as described earlier. This transition of the signal ^ from 0 to 1 allows the stationary center to recognize the status of the handset of the mobile subscriber, and indeed the stationary center recognizes in this case that the mobile subscriber has answered the call.

Let us now consider the circuits that are involved in the triggering at the end of the conversation. A distinction must be made between the two cases where the end of the conversation is brought about by the stationary or the mobile subscriber. If the stationary subscriber hangs up first, the logic circuits of the mobile subscriber register the receipt of the trigger signal C from the stationary to the moving subscriber via the monitoring signal decoder, which corresponds to the activation of the output of the NAND circuit 106 of the monitoring signal decoder DSS , that is, the signal C goes from 1 to 0 over. As a result, the output of the NAND circuit 112 changes from 1 to 0 and the switch-on memory is reset to the idle state.

Before examining the case where the mobile subscriber hangs up first, consider the operation of the delay counter circuit CR. This circuit is used on the one hand to measure the time in which the mobile receiver is "fading" and on the other hand to measure the time set for the transmission of the trigger signal from the mobile to the stationary subscriber.

The fact that the mobile subscriber hangs up first causes the return of the signal C to the logic value_0, and therefore the return of the signal C to 1 via the NAND circuit 135 causes the signal H to return to 0, which in FIG In this case, the meaning of the trigger signal \ om moving to the stationary participant takes over. In addition, it sets the counting of the delay counter in motion via the bistable multivibrator Bg and the NAND circuits 133 and 117 and enables the operation of the circuit which detects the expiry of the programmed delay time via the NAND circuits 119 and 120.

The output of the NAND circuit 120 changes from the logic value 1 to the logic value 0 and caused by the NAND circuit 113 changing accordingly from 0 to 1 and the corresponding from 1 to 0 changing NAND circuit 112 the return of the switch-on memory to the idle state and thus the Return of the whole movable device to the idle state.

The delay counter is also used to measure the duration of the "fading" present on the receiver of the mobile participant. As soon as the mobile receiver no longer receives a carrier frequency, the Prf signal changes from 1 to 0. This causes the delay counter to start counting via the NAND circuits 115, 116 and 117 and activates the output of the NAND circuit 118, which changes from 1 to 0 as soon as the intended delay is reached. This causes the switch-on memory to return to the idle state via the NAND circuits 113 and 112.

The connector at the output of the delay counter is used to program both the duration of the triggering signal from the mobile to the stationary subscriber as well as the duration of the "Fadimg" control before the mobile device is triggered. Fs, Fe, Fi are signals that come from the monitoring and reporting receiver R _x S.

In addition 5 sheets of drawings

Claims (2)

Patent claims: 1. Movable subscriber set for a radio telephone system cooperating with the public telephone network, consisting of a control panel and a unit equipped with logic circuits, which controls the radio channel selection and the transmission of the own identification number and the dial number of the subscriber to be called to a transceiver and which controls and Exchanges message signals directly with your transceiver and with a signal receiver, which in turn exchanges message signals with the logic unit and the transceiver, characterized by a program control unit (ErJt which receives a signal indicating the position of the hybrid circuit of the handset and a call signal coming from the fixed switching center and receives the Transceiver (R _x T _x J, based on the channel occupied by the mobile subscriber during the previous call, successively tunes to the call channels;
through an identification and selection distributor (DIS), which receives a signal indicating that the handset has been picked up or the reception of a call sign and the digits of the own identification number or the dialing number of the called subscriber, encoded in a 2-out-of-6 code, to a signal generator Control unit (CG) sends, instead of the second, fourth, sixth, etc. digit of a sequence of identical digits, a code combination for a repetitive character is sent and the code combinations sent to the signal generator control unit (CG) are divided up in such a way that In each case a higher-valued code step acts on a first generator (C2) and a lower-valued code step acts on a second generator (Gi) Selected second subscriber apparatus according to claim 1, characterized by a matrix (Mj) for generating binary control signal for the formation of the audio signals corresponding to the to be transmitted choice digits w in an election preparer (PRSE) under of electrical connection of the rails of the same immediately consecutive digits are; a series of NAN D circuits (41 to 49), each of which compares two consecutive digits with each other by evaluating the signals that are present on the rails of the to dial preparer (PrSe) and corresponding to the digits in question and in the event that two consecutive digits are equal enables the code combination for a repetition character and at the same time stores the transmission of the repetition character in a memory element (Fi), this memory information enabling the transmission of the code combination of the following digit even if this digit is again equal to the ω immediately preceding digits